ライフサイエンスコーパス: corona radiata

1 tional anisotropy in the corpus callosum and corona radiata.

2 d increased mean diffusivity of the anterior corona radiata.

3 , predominantly in the centrum semiovale and corona radiata.

4 ddle frontal gyrus white matter and anterior corona radiata.

5 posterior limb of the internal capsule, and corona radiata.

6 al anisotropy in the corpus callosum and the corona radiata.

7 e left thalamic radiation and right anterior corona radiata.

8 within a ROI in the left hemisphere anterior corona radiata.

9 the superior longitudinal fasciculus and the corona radiata.

10 zona pellucida matrix and had a disorganized corona radiata.

11 ) in two brain regions: the thalamus and the corona radiata.

12 ces were observed in the corpus callosum and corona radiata.

13 well as the bilateral anterior and superior corona radiatas.

14 rls showed persistently lower FA in anterior corona radiata (ACR) (group, P = .04; group x age x sex,

15 Greater FA in the anterior corona radiata (ACR) was associated with better inhibiti

16 asciculus, posterior thalamic radiation, and corona radiata (all p < 0.05).

17 ying white matter microstructure at the left corona radiata and also associated with overall symptoms

18 ts, with the highest lesion frequency in the corona radiata and between C2 and C4 vertebral levels.

19 -0.02 (P = .02); MD, beta = -0.01 (P = .03)] corona radiata and external capsule [right FA, beta = 0.

20 ractional anisotropy in the corpus callosum, corona radiata and external capsule, and increased mean

21 actional anisotropy were evident only in the corona radiata and genu of the corpus callosum.

22 tions of the corpus callosum and beyond (eg, corona radiata and inferior longitudinal fasciculus) acr

23 or component of the motor system through the corona radiata and internal capsule are well described i

24 largest centered bilaterally in the superior corona radiata and subcortical gray and white matter (cl

25 The loading factor in the anterior corona radiata and temporo-parieto-frontal components we

26 tropy than control subjects in the posterior corona radiata and the optic radiation (P < 0.002).

27 erior limb of the internal capsule, superior corona radiata, and cerebellar peduncles), the associati

28 corpus callosum (CC) and bilateral anterior corona radiata, and higher FW in the body of the CC comp

29 Parietal operculum, corona radiata, and internal capsule differences between

30 rior limb of the internal capsule, posterior corona radiata, and partly in the left sagittal stratum.

31 matter (in corpus callosum, cingulum bundle, corona radiata, and superior fronto-occipital fasciculus

32 ingulum, fornix, stria terminalis, posterior corona radiata, and superior longitudinal fasciculus in

33 lum, fornix, and stria terminalis, posterior corona radiata, and superior longitudinal fasciculus.

34 corpus callosum, the superior and posterior corona radiata, and the cingulum.

35 onal anisotropy (optic radiations, posterior corona radiata, and the splenium region of the corpus ca

36 ferior fronto-occipital fasciculus, superior corona radiata, and uncinate fasciculus.

37 al superior longitudinal fasciculi, superior corona radiata, anterior thalamic radiations, and poster

38 ant differences also emerged in the anterior corona radiata as well as in white matter underlying the

39 ior longitudinal fasciculus, right posterior corona radiata, as well as the bilateral anterior and su

40 l control and FA in left hemisphere anterior corona radiata, as well as the correlation between memor

41 of internal capsule, superior and posterior corona radiata, bilateral external capsule and the right

42 d increases in MD in the bilateral posterior corona radiata, bilateral superior longitudinal fascicul

43 ous tracts including the corpus callosum and corona radiata compared to mature-born adults.

44 uperior longitudinal fasciculus and superior corona radiata) compared to controls (adjusted-p values

45 co-cortical and cortico-thalamic fibers: the corona radiata, corpus callosum, superior longitudinal f

46 est analysis included anterior and posterior corona radiata, cortico-spinal tracts, cingulum fibre bu

47 zation of the corticofugal projection in the corona radiata (CR) and internal capsule (IC) can assist

48 dal cingulate (M4) motor regions through the corona radiata (CR), internal capsule (IC) and crus cere

49 (CC), superior longitudinal fasciculus (LF), corona radiata (CR), internal capsule (IC) and external

50 nal fasciculus (Cohen's d = 0.37), posterior corona radiata (d = 0.32), and superior fronto-occipital

51 The anterior corona radiata (d=0.40) and corpus callosum (d=0.39), sp

52 was whole-brain FA in parts of the anterior corona radiata, external capsule, and cerebellum (P<0.05

53 tion between memory performance and anterior corona radiata FA.

54 , with no such relationships observed in the corona radiata for any of the metabolites examined.

55 9) evidenced higher FA in the right superior corona radiata, higher FA and AD in bilateral corticospi

56 ody of the corpus callosum and left anterior corona radiata in individuals with HUD correlated with a

57 ean orientation dispersion index in superior corona radiata in males.

58 mm3 [95% CI, 5.5-13.4 mm3]), left posterior corona radiata (intensive treatment, 26.0 mm3 [95% CI, 1

59 ep white matter regions of the left anterior corona radiata (intensive treatment, 30.3 mm3 [95% CI, 1

60 egions of interest in the centrum semiovale, corona radiata, internal capsule, corpus callosum, and s

61 -brain and specific brain regions (including corona radiata, internal capsule, superior and inferior

62 or G carrier genotypes in the left and right corona radiata, left uncinate fasciculus, left inferior

63 ecifically by axial diffusivity of the right corona radiata, (maximum indirect effect beta = -0.034 (

64 ng the anterior thalamic radiation, anterior corona radiata, or external capsule.

65 internal capsule, callosal isthmus, and the corona radiata (p=0.04 for FIQ and p=0.01 for PIQ, corre

66 the posterior limb of the internal capsule, corona radiata, posterior frontal white matter, and pari

67 ed by a higher fractional anisotropy of left corona radiata, predicted fewer inhibitory deficits, sug

68 e matter microstructure (e.g. genu, anterior corona radiata), rather than posterior (e.g. splenium, p

69 A) in callosal and projection fibers (IC and corona radiata) relative to controls, but lower FA than

70 ood ADHD in the right superior and posterior corona radiata, right superior longitudinal fasciculus,

71 tracts, specifically within right posterior corona radiata, right tapetum, and bilateral corpus call

72 um of corpus callosum, anterior and superior corona radiata, superior longitudinal and inferior front

73 respectively, including the corpus callosum, corona radiata, superior longitudinal fasciculus, and co

74 LIC, the cerebral peduncle, and the superior corona radiata than did the HC.

75 her than posterior (e.g. splenium, posterior corona radiata)-the mediatory effect of anterior white m

76 white matter microstructure of the anterior corona radiata, then cognition (working memory, focused

77 tivity to the optic radiations and posterior corona radiata tracts (P < 0.05).

78 in patients with NMO, mainly located in the corona radiata, uncinate fasciculus, corpus callosum, op

79 corpus callosum, longitudinal fasciculus and corona radiata were independent contributors to the Brie

80 l-motor cortex FC significantly mediated the corona radiata white matter effects on SICI (p = .007).